What question did this study set out to answer?

Investigate how positional isomerism affects the diradical character of imidazole-linked quinoidal systems.

March 26, 2026

Modulation of Open-Shell Diradical Character of Imidazole Quinoidal Systems

Key Points

Investigate how positional isomerism affects the diradical character of imidazole-linked quinoidal systems.
Synthesis of imidazole-linked quinoidal isomers at 2,2' and 4,4'-positions.
Assessment of diradical character through variable-temperature 1H NMR and EPR spectroscopy.
DFT calculations to analyze electronic structure.
Isomer I1a shows weak open-shell diradical character (y0 ≈ 0.2), while isomers I2a-I2c exhibit strong diradical character (y0 ≥ 0.5).
Enhanced π-electron delocalization in 4,4'-linked isomers contributes to increased diradical character.
All synthesized isomers maintain solid-state stability for over one year under ambient conditions.

Abstract

We report imidazole-linked quinoidal constitutional isomers with aryl substituents connected at the 2,2'- (I1a) and 4,4'-positions (I2a-I2c), enabling systematic modulation of diradical character through positional isomerism. Despite identical molecular compositions, I1a adopts a weak open-shell diradical character (diradical character, y0 ≈ 0.2), whereas the 4,4'-linked isomers I2a-I2c exhibit pronounced open-shell diradical character (y0 ≥ 0.5). This difference arises from enhanced π-electron delocalization between the quinoidal core and aryl substituents in the 4,4'-connected framework. Variable-temperature 1H NMR, EPR spectroscopy, and DFT calculations confirmed the open-shell nature. All isomers exhibit excellent solid-state stability under ambient conditions for over one year. These findings establish positional isomerism as an effective strategy for tuning and stabilizing open-shell diradical systems.

Bookmark

Modulation of Open-Shell Diradical Character of Imidazole Quinoidal Systems

Key Points

Abstract

Cite This Study